Small profile pressure and temperature gauges

ABSTRACT

Small profile apparatus for pressure and/or temperature sensing within a wellbore are provided. The apparatus may include optical sensing assemblies designed for inclusion in traditional or coiled production tubing deployments and suitable for use in high pressure, high temperature environments. One example assembly generally includes an outer housing, an inner housing at least partially disposed in the outer housing, a port for fluid communication between an internal volume of the inner housing and a volume external to the outer housing, and a large diameter optical waveguide disposed in the internal volume of the inner housing. The waveguide includes a first portion with a first grating and a second portion with a second grating, wherein the outer diameter of the large diameter optical waveguide is at least 300 μm.

CLAIM OF PRIORITY UNDER 35 U.S.C. § 119

This application is a divisional of U.S. patent application Ser. No.14/330,338, filed Jul. 14, 2014 and entitled “Small Profile Pressure andTemperature Gauges,” which is herein incorporated by reference in itsentirety.

BACKGROUND OF THE INVENTION

Field of the Invention

Embodiments of the invention generally relate to sensors and, moreparticularly, to small form-factor pressure or temperature sensingassemblies, suitable for hydrocarbon production.

Description of the Related Art

Many industries and applications utilize sensors to measure parameters,such as pressure or temperature. In some cases, such sensors may utilizeoptical waveguides having a grating, such as a Bragg gratings orFabry-Perot cavities, and the optical waveguides may have acharacteristic wavelength reflectivity at a given pressure and/ortemperature. As pressure and/or temperature change, the reflectivitycharacteristics of an optical waveguide may change in a predictablemanner. Based on pressure and/or temperature-induced changes in thegrating of a waveguide, a sensing device can determine changes inpressure and temperature by injecting a light pulse into an opticalwaveguide and measuring the reflected wavelength.

Such optical sensors may be used for sensing pressure and/or temperaturein production tubing located in a wellbore completion for producinghydrocarbons. Traditional tubing strings, in which multiple lengths oftubing are coupled together, or coiled tubing may be deployed in thewellbore completion. In coiled tubing deployments, a length of tubing,which may be of a length appropriate for the depth of the completion,may be spooled onto a take-up reel. During installation, the tubing canbe straightened and, using an injector head, can be run into thecompletion. Because coiled tubing is meant to be spooled onto andunspooled from a reel, the diameter of a coiled tube may be less thanthe diameter of traditional production tubing.

Several challenges exist with constructing optical sensors for use inproduction tubing, especially for coiled tubing deployments. One ofthese challenges involves the size of such sensors. While opticalsensors for installation in traditional production tubing exist, variousfactors, including susceptibility of the glass fiber to damage andbreakage due to its small size, flexibility, and brittle nature, make itdifficult to build optical sensors for installation in more compactproduction tubing (e.g., coiled tubing deployments). For example, aconventional sensing gauge may be ¾″ in diameter and about 15″ long andmay not fit within a coiled tubing.

There is a need, therefore, for a compact optical sensor assemblycapable of operating in relatively high temperature and high pressureenvironments and deployable in various types of traditional and coiledproduction tubing.

SUMMARY OF THE INVENTION

Embodiments of the present invention generally relate to pressure and/ortemperature sensing configurations that may be packaged in a smalldiameter form-factor. Such configurations may be suitable for use incoiled tubing employed for hydrocarbon production.

One embodiment of the invention is an optical sensing assembly. Theassembly generally includes a housing having a divider for separating afirst volume from a second volume inside the housing, a compressibleelement disposed in the first volume, wherein a first end of thecompressible element is coupled to the divider and a second end of thecompressible element is sealed, and a large diameter optical waveguidedisposed in an internal volume of the compressible element. Thewaveguide typically includes a first portion with a first grating and asecond portion with a second grating, wherein the first portion has agreater outer diameter than the second portion and wherein the outerdiameter of the second portion is at least 300 μm.

Another embodiment of the invention is an optical sensing assembly. Theassembly generally includes a housing; wherein a portion of a wall ofthe housing includes a flexible member; a compressible frame assemblydisposed in the housing, wherein a first end of the frame assembly iscoupled to the flexible member and wherein a second end of the frameassembly is coupled to an inner surface of the housing; and a largediameter optical waveguide held by the frame assembly and having a firstgrating disposed in a first portion of the waveguide and a secondgrating disposed in a second portion of the waveguide, wherein an outerdiameter of the large diameter waveguide is at least 300 μm.

Yet another embodiment of the invention is an optical sensing assembly.The assembly generally includes a housing (including a divider forseparating a first volume from a second volume inside the housing and aport disposed in an end of the housing); a compressible element disposedin the first volume, wherein a first end of the compressible element iscoupled to the end of the housing, wherein a second end of thecompressible element is sealed, and wherein an internal volume of thecompressible element is in fluid communication with the port; and alarge diameter optical waveguide coupled to the divider and to thesecond end of the compressible element. The waveguide typically has afirst grating disposed in a first portion of the waveguide and a secondgrating disposed in a second portion of the waveguide. An outer diameterof the large diameter optical waveguide is at least 300 μm.

Yet another embodiment of the invention is an optical sensing assembly.The assembly generally includes an outer housing (including a dividerfor separating a first volume from a second volume inside the outerhousing and a port through the outer housing to the first volume); acompressible element disposed in the first volume, wherein a first endof the compressible element is coupled to the divider and wherein asecond end of the compressible element is sealed; an inner housingdisposed in the second volume, wherein a first end of the inner housingis coupled to the divider; a large diameter optical waveguide at leastpartially disposed in the inner housing and coupled to a second end ofthe inner housing; and a rod disposed in an internal volume of thecompressible element and passing through a bore in the divider, whereina first end of the rod is coupled to the second end of the compressibleelement and a second end of the rod is coupled to the large diameterwaveguide. The waveguide typically has a first portion with a firstgrating and a second portion with a second grating. An outer diameter ofthe large diameter optical waveguide is at least 300 μm.

Yet another embodiment of the invention is an optical sensing assembly.The assembly generally includes a housing having a port through a wallof the housing; an expandable tube having an internal volume and aninlet coupled to the port of the housing for fluid communication betweenthe internal volume of the expandable tube and an external volume of thehousing; first and second holding members coupled to the expandabletube; and a large diameter optical waveguide held by the first andsecond holding members. The waveguide typically has a first portion witha first grating and a second portion with a second grating. An outerdiameter of the large diameter optical waveguide is at least 300 μm.

Yet another embodiment of the invention is an optical sensing assembly.The assembly generally includes an outer housing; an inner housing atleast partially disposed in the outer housing; a port for fluidcommunication between an internal volume of the inner housing and avolume external to the outer housing; and a large diameter waveguidedisposed in the internal volume of the inner housing. The waveguidetypically has a first portion with a first grating and a second portionwith a second grating. An outer diameter of the large diameter opticalwaveguide is at least 300 μm.

BRIEF DESCRIPTION OF THE DRAWINGS

So that the manner in which the above-recited features of the presentinvention can be understood in detail, a more particular description ofthe invention, briefly summarized above, may be had by reference toembodiments, some of which are illustrated in the appended drawings. Itis to be noted, however, that the appended drawings illustrate onlytypical embodiments of this invention and are therefore not to beconsidered limiting of its scope, for the invention may admit to otherequally effective embodiments.

FIG. 1 is a schematic cross-sectional view of an example wellboreaccording to an embodiment of the present invention.

FIG. 2 is a schematic cross-sectional view of a small profile opticalsensing assembly with an optical sensor disposed in a compressibleelement and axially reactive to pressure changes, according to anembodiment of the present invention.

FIG. 3 is a schematic cross-sectional view of a small profile opticalsensing assembly with an optical sensor held by a frame assembly suchthat radial pressure changes are translated to axial forces on thesensor, according to an embodiment of the present invention.

FIG. 4 is a schematic cross-sectional view of a small profile opticalsensing assembly with an optical sensor disposed outside a compressibleelement and axially reactive to pressure changes, according to anembodiment of the present invention.

FIG. 5A is a schematic cross-sectional view of a side-ported smallprofile optical sensing assembly with an optical sensor disposed insidean internal framing and axially reactive to pressure changes impartedthrough a compressible element, according to an embodiment of thepresent invention.

FIG. 5B is a schematic cross-sectional view of a side-ported smallprofile optical sensing assembly with a dog-bone optical sensor disposedinside an internal framing and axially reactive to pressure changesimparted through a compressible element according to an embodiment ofthe present invention.

FIG. 6A is a schematic cross-sectional view of a side-ported smallprofile optical sensing assembly with an optical sensor partiallydisposed within a flexible member and disposed inside an internalframing, and axially reactive to pressure changes imparted through acompressible element, according to an embodiment of the presentinvention.

FIG. 6B illustrates an example flexible member that may be disposedaround at least a portion of the optical sensor in FIG. 6A, according toan embodiment of the present invention.

FIG. 7 is a schematic cross-sectional view of a side-ported smallprofile optical sensing assembly with an optical sensor disposed in anexpandable tube and axially reactive to pressure changes impartedthrough the expansion or contraction of the expandable tube, accordingto an embodiment of the present invention.

FIG. 8 is a schematic cross-sectional view of an internally ported smallprofile optical sensing assembly having an optical sensor disposedwithin an internal housing and radially reactive to pressure changesimparted by fluids entering the internal housing, according to anembodiment of the present invention.

DETAILED DESCRIPTION

Embodiments of the present invention provide apparatus for performingpressure and/or temperature sensing within a wellbore. The apparatus maybe suitable for inclusion in traditional tubing or in coiled tubingdeployments and may be suitable for use in high pressure, hightemperature environments, such as a downhole environment havingtemperatures in excess of 250° C.

FIG. 1 illustrates a schematic cross-sectional view of an examplewellbore 102. Wellbore 102 may have a casing 104 disposed within,through which production tubing 106 may be deployed as part of awellbore completion. Hydrocarbons located in a reservoir 108 may beproduced through tubing 106 using natural lift or artificial lift means.A sensing unit 110 may be used to perform sensing of a variety ofparameters in a wellbore. Sensing unit 110 may be, for example, anoptical system comprising an optic signal generator and a receiver forreceiving data from sensors in the wellbore.

The sensing unit 110 may be connectively coupled to one or more sensors112 positioned in the production tubing 106 via an optical waveguide,such as an optical fiber 114 or a cable including multiple opticalfibers. Sensors 112 may be, for example, a pressure and/or temperaturegauge. For example, one sensor 112 may be positioned in a firstproduction zone (e.g., for producing gaseous products), a second sensor112 may be positioned in a second production zone (e.g., for producinghydrocarbon liquids), and so on. For some embodiments, the sensing unit110 may utilize a single fiber within a suspended cable deployed inproduction tubing 106, in a cable coupled to the outside of theproduction tubing 106 (i.e., in the annulus between the casing 104 andthe tubing 106), or in a cable external to the casing 104.

Sensors 112 may be single-ended or pass-through sensors. A single-endedsensor has a single optical waveguide coupled to the sensor and istypically positioned at the end of this optical waveguide. A pulse oflight may enter the sensor through the single optical waveguide, andreflected light may be received at sensing unit 110 via the singleoptical waveguide. A pass-through sensor may be coupled (e.g., via apigtail) to an optical waveguide at each end of the sensor, for example.Light may enter the sensor through a first optical waveguide, passthrough the sensor to a second waveguide, and be transmitted to anothersensor coupled to the second waveguide. Reflections from the sensor(s)may travel through the first optical waveguide to sensing unit 110.

For some embodiments, a coupler may be connected with a single-endedsensor in order to have light travel to one or more additional sensorslinked to the single-ended sensor. By using one or more couplers,multiple single-ended sensors may be linked.

Example Sensing Assembly with Encased Cane Element

FIG. 2 illustrates an embodiment of a small profile optical sensingassembly 200 suitable for measuring pressure and/or temperature. Sensingassembly 200 may include a housing 202 having a divider 204 that mayseparate a first volume 203 from a second volume 205 in housing 202. Acompressible element 206 (e.g., a bellows assembly) may be disposed inthe first volume 203. A first end of compressible element 206 may beattached or otherwise mechanically coupled to divider 204, and a secondend of compressible element 206 may be sealed (e.g., with an end cap220). Wellbore fluids may be present in at least the first volume 203,whereas the second volume 205 is isolated from the wellbore fluids.

A large diameter optical waveguide 208 may be disposed in an internalvolume of the compressible element. As used herein, a large diameteroptical waveguide (also referred to as a “cane” waveguide due to itsrelatively rigid nature compared to an optical fiber) generally refersto a waveguide having a cladding surrounding a core, wherein an outerdiameter of the cladding is at least 300 μm. Optical waveguide 208 mayhave a first portion 210 with a first Bragg grating 212 and a secondportion 214 with a second Bragg grating 216. The first portion 210 has agreater outer diameter than the second portion 214, and the outerdiameter of second portion 214 may be at least 300 μm. For someembodiments, the large diameter optical waveguide 208 may be amonolithic glass assembly, composed of a single piece of glass ormultiple pieces fused together to form the monolith.

In an embodiment, sensing assembly 200 may be packaged in a ⅜ inch (⅜″)or smaller outer diameter housing 202. In this manner, the sensingassembly 200 is suitable for deployment in coiled tubing, as well as intraditional production tubing.

In an embodiment, compressible element 206 is a bellows assembly. Thebellows assembly may be, for example, an edge-welded bellows (alsoreferred to as diaphragm bellows), convoluted bellows (also known asformed bellows), or any other type of bellows assembly appropriate foruse in a downhole production environment. The bellows assembly providesfluid isolation between the first and second volumes 203, 205 andamplification of the fluid pressure in the first volume 203.

In an embodiment, large diameter optical waveguide 208 may have a“dog-bone” shape, which has two piston portions connected by a pistonrod as illustrated in FIG. 2. First portion 210 of the waveguide 208 maybe a piston portion, and second portion 214 may be a narrow portion(i.e., the piston rod) as depicted. Large diameter optical waveguide 208may further include a third portion 218, which may have a greater outerdiameter than second portion 214. The outer diameter of the first andthird portions may be equal. Third portion 218 may be configured tointeract with the second end of compressible element 206.

For some embodiments, first portion 210 of optical waveguide 208 may becoupled (e.g., via a pigtail) to an optical fiber 222 that propagateslight to interrogate the first and second gratings 212, 216. In anembodiment, optical fiber 222 may pass from the waveguide 208 through abore in divider 204 to the cable with optical fiber 114, such that thegratings 212, 216 may be interrogated by the sensing unit 110.

For some embodiments, divider 204 may include a frustoconical seat formating with the first portion 210 of optical waveguide 208. Whencompressible element 206 is compressed axially 224, large diameteroptical waveguide 208 may be forced axially against the seat. A firstend of compressible element 206 may be mounted to divider 204 such thatcompressible element 206 compresses or expands axially in response tochanges in pressure of wellbore fluids in the first volume 203.

For some embodiments, large diameter optical waveguide 208 may bedisposed in the internal volume of compressible element 206 such thatcompression or expansion of compressible element 206 increases ordecreases strain on the waveguide 208, thereby changing thecharacteristic wavelengths of the first and second gratings.

During operation, sensing assembly 200 may be positioned withinproduction tubing 106 such that one end of compressible element 206 isin fluid communication with wellbore fluids within the productiontubing, which may impart axial loading on compressible element 206. Asthe pressure within the wellbore varies, the axial loading oncompressible element 206 may also change, which may in turn alter thecompression imparted to optical waveguide 208 and, hence, thecharacteristic wavelengths of gratings 212 and 216. Interrogation ofgratings 212 and 216 by sensing unit 110 may thus be used to detectchanges in pressure and/or temperature at the location of sensingassembly 200.

Example Sensing Assembly with Frame-Mounted Cane Element with SideLoading

FIG. 3 illustrates another embodiment of a small profile pressure andtemperature sensing assembly 300. Sensing assembly 300 may be one of thesensors 112 deployed in the production tubing 106 as described abovewith respect to FIG. 1. As such, sensing assembly 300 may be designed tooperate in environments having an ambient temperature greater than 250°C.

Sensing assembly 300 may include a housing 302, a compressible frameassembly 304, and a large diameter optical waveguide 306. In someembodiments, housing 302 may be composed of an outer tubing having anouter diameter of at most ⅜ inches, which may be suitable for deployingthe assembly in coiled tubing. A portion of a wall of housing 302 maycomprise a flexible member 308 configured to respond to changes inpressure external to the housing. For example, flexible member 308 maybe a bellows assembly or a diaphragm. Compressible frame assembly 304may be disposed in housing 302. A first end of frame assembly 304 may becoupled to flexible member 308, and a second end of frame assembly 304may be coupled to an inner surface of housing 302, which may be oppositethe flexible member 308.

Large diameter optical waveguide 306 may be held by frame assembly 304and may have a first grating 312 disposed in a first portion 310 ofwaveguide 306 and a second grating 316 disposed in a second portion 314of waveguide 306. The outer diameter of the large diameter opticalwaveguide may be at least 300 μm. For some embodiments, large diameteroptical waveguide 306 may be a monolithic glass assembly.

For some embodiments, first portion 310 of waveguide 306 may bepositioned inside frame assembly 304 (e.g., with no part of firstportion 310 protruding from the frame assembly), second portion 314 ofwaveguide 306 may protrude from frame assembly 304, and the secondgrating 316 may be disposed outside frame assembly 304, as depicted inFIG. 3. In another embodiment, first portion 310 and second portion 314of waveguide 306 may be positioned inside frame assembly 304, such thatfirst and second gratings 312, 316 are both disposed inside the frameassembly.

In an embodiment, large diameter optical waveguide 306 may have a“dog-bone” shape as described above. First portion 310 may include anarrow portion of the dog-bone shape, and second portion 314 may includea piston portion of the dog-bone shape.

A first end of waveguide 306 may be coupled to a first optical fiber 318that propagates light to interrogate the first and second gratings. Asecond end of waveguide 306 may be coupled to a second optical fiber 320that propagates light to an optical device, such as another sensingassembly or a fiber Bragg grating (FBG). Assembly 300 may be asingle-ended assembly (i.e., an assembly at the end of a fiber opticstrand) or a pass-through assembly (i.e., an assembly allowing otherfiber optic sensors to be coupled via additional lengths of opticalfiber).

Flexible member 308 may be configured to interact with a fluid outsidehousing 302, and a first end of compressible frame assembly 304 may becoupled to flexible member 308 such that the frame assembly compressesor expands radially in response to changes in pressure or temperature ofthe fluid. Large diameter optical waveguide 306 may be mounted incompressible frame assembly 304 such that when frame assembly 304 iscompressed radially, large diameter optical waveguide 306 is expandedaxially. Frame assembly 304 may act as a mechanical amplifier whentranslating the movement of flexible member 308 to optical waveguide306, thereby increasing the sensitivity of the sensing assembly. In anembodiment, the first grating 312 may be sensitive to changes inpressure of the fluid, and the second grating 316 may not be sensitiveto these changes. Both gratings may be sensitive to temperature.

In an embodiment, large diameter optical waveguide 306 may have one ormore features to assist holding of the waveguide by frame assembly 304.For example, optical waveguide 306 may have one or more membersconfigured to be grasped by a clamp, may be shaped such that one or moremembers of optical waveguide 306 can be held in place by frame assembly304, or any other feature allowing the waveguide 306 to be held by theframe assembly 304.

In operation, sensing assembly 300 may be positioned in productiontubing 106 such that the wall of housing 302 (e.g., a portion of thewall opposite flexible member 308) is attached, mounted, or otherwisemechanically coupled to the production tubing and such that flexiblemember 308 is in fluid communication with wellbore fluids in theproduction tubing. Pressure changes imparted on flexible member 308cause frame assembly 304 to expand or contract radially within housing302, which leads the frame assembly 304 to shorten or lengthen axially,respectively. Namely, as pressure imparted on flexible member 308increases, frame assembly 304 extends a greater axial distance, and aspressure imparted on flexible member 308 decreases, frame assembly 304shortens axially. The axial expansion or contraction of frame assembly304 imparts axial force (pulling or pushing, also referred to asstraining or compressing) on optical waveguide 306, causing opticalwaveguide 306 to lengthen or shorten axially, respectively, in reactionto force exerted radially on housing 302. The expansion or contractionof optical waveguide 306 causes the characteristic wavelength ofgratings 312 and/or 316 to change. An interrogation may be performed bysensing unit 110 by transmitting one or more pulses of light to gratings312 and/or 316, and the reflected wavelength from gratings 312 and/or316 may be used to determine pressure and/or temperature at the locationof sensing assembly 300.

Example Sensing Assembly Having Frame-Mounted Cane Element with EndLoading

FIG. 4 illustrates an embodiment of a small profile pressure andtemperature sensing assembly 400. Sensing assembly 400 may be one of thesensors 112 deployed in the production tubing 106 as described abovewith respect to FIG. 1. As such, sensing assembly 400 may be designed tooperate in environments having an ambient temperature in excess of 250°C. Sensing assembly 400 may include a housing 402, a compressibleelement 404, and a large diameter optical waveguide 406.

Housing 402 may have a divider 408 for separating a first volume 403from a second volume 405 inside the housing and a port 410 disposed inan end of the housing through which fluid may pass. Housing 402 may becomposed of an outer tubing having an outer diameter of at most ⅜ incheswhich may be suitable for use in coiled tubing deployments, as well asin traditional production tubing. For some embodiments, the sensingassembly 400 may fit inside a small diameter tube (e.g., ¼″).

Compressible element 404 (e.g., a bellows assembly or a diaphragm) maybe disposed in first volume 403. A first end 412 of compressible element404 may be attached, mounted, or otherwise coupled to the end of housing402, and a second end 414 of compressible element 404 may be sealed(e.g., with an end cap). An internal volume of compressible element 404may be in fluid communication with port 410 of housing 402 such thatwellbore fluids (e.g., in production tubing 106 external to housing 402)may interact with second end 414, forcing compressible element 404 tocompress or expand axially as the pressure of the wellbore fluidsdecreases or increases, respectively.

Waveguide 406 may be disposed between and mechanically coupled todivider 408 and second end 414. For some embodiments, waveguide 406 mayhave a first grating 426 disposed in a first portion 416 of waveguide406 and may have a second grating 428 disposed in a second portion 418of waveguide 406. For other embodiments, waveguide 406 may have firstgrating 426 disposed in a part of second portion 418 protruding into abore of divider 408 and may have second grating 428 disposed in anotherpart of second portion 418 located in first volume 403, as illustratedin FIG. 4. In this manner, the second grating 428 may be sensitive tothe pressure applied via the port 410, while the first grating 426 maynot be, such that the sensing assembly 400 may act as a pressure andtemperature sensor. The outer diameter of large diameter opticalwaveguide 406 may be at least 300 μm, including the first portion 416.For some embodiments, waveguide 406 may be a monolithic glass assembly.

Divider 408 may have or may be coupled to a first seat 409 (e.g., afrustoconical seat) configured to receive and mate with second portion418 of waveguide 406. Waveguide 406 may be coupled to divider 408 viathe first seat 409 such that when compressible element 404 is expandedaxially, waveguide 406 is forced axially against the first seat. Secondend 414 of compressible element 404 may include or may be coupled to asecond seat 413 configured to receive and mate with a third portion 419(e.g., a piston portion) of waveguide 406. Waveguide 406 may be coupledto second end 414 via the second seat, such that when compressibleelement 404 is expanded axially, second seat 413 is forced axiallyagainst third portion 419. Waveguide 406 may have one or more featuresto assist coupling of the waveguide to at least one of first seat 409 orsecond seat 413.

In an embodiment, one or more flexible members 424 may be coupledbetween second seat 413 and one or more sidewalls of housing 402 asshown in FIG. 4. These flexible members 424 may be used, for example, tohelp maintain the force on waveguide 406 in an axial direction, suchthat there is a reduced or no radial force vector component. In otherwords, the loading of waveguide 406 is coaxial with the mounting of thewaveguide within housing 402 by flexible members 424.

For some embodiments, second seat 413 may include or be coupled to aball (not shown) for contact between the second seat and second end 414of compressible element 404. This ball contact may assist compression ofsecond seat 413 and waveguide 406, even when the forces on the secondend of the compressible element are not perfectly aligned with housing402 (i.e., not axial).

In an embodiment, a biasing element may be used to maintain waveguide406 in compression. The biasing element may include, for example, one ormore pre-load pins 420 between second seat 413 and second end 414 ofcompressible element 404, as portrayed in FIG. 4. The one or morepre-load pins may be, for example, affixed in position (e.g., bywelding) with the compressible element in a compressed state and largediameter optical waveguide 406 mounted between first and second seats409, 413.

For some embodiments, waveguide 406 may have a “dog-bone” shape,comprising first, second, and third portions 416, 418, 419. Firstportion 416 may include a narrow portion of the dog-bone shape, which isdisposed in first volume 403. Second portion 418 may include a pistonportion of the dog-bone shape, and third portion 419 may include anotherpiston portion.

Waveguide 406 may be coupled (e.g., via a pigtail) to an optical fiber422 that propagates light to interrogate first and second gratings 426,428. Optical fiber 422 may pass from second portion 418 through a borein divider 408 to second volume 405. Optical fiber 422 may be coupled tooptical fiber 114 via fiber splicing, for example.

In operation, sensing assembly 400 may be positioned within productiontubing 106 such that compressible element 404 is in fluid communicationwith wellbore fluids within the production tubing via port 410. As thepressure of the wellbore fluids increases within the internal volume ofcompressible element 404, the fluids push harder against second end 414,thereby further axially compressing waveguide 406. In contrast, as thepressure of the wellbore fluids decreases, the force on the second end414 of compressible element 404 lessens, thereby reducing the axialcompression on waveguide 406. The changes in axial compression causechanges to the reflectivity characteristics of gratings 426 and 428,which may be amplified by the dog-bone shape of waveguide 406. Sensingunit 110 may interrogate gratings 426 and/or 428 and, based on thereflected Bragg wavelength of the gratings, determine pressure and/ortemperature at the location of sensing assembly 400.

Example Sensing Assembly Having Frame-Mounted Cane Element withSide-Ported Fluid Entry

FIGS. 5A and 5B illustrate embodiments of a small profile pressure andtemperature sensing assembly 500. Sensing assembly 500 may be one of thesensors 112 deployed in the production tubing 106 as described abovewith respect to FIG. 1. As such, sensing assembly 500 may be designed tooperate in environments having an ambient temperature in excess of 250°C.

Sensing assembly 500 may include an outer housing 502, divider 504,fluid entry port 506, compressible element 508, inner housing 510,pressure imparting member (e.g., a rod) 512, and large diameter opticalwaveguide 518. Divider 504 may separate a first volume 503 from a secondvolume 505 inside outer housing 502. Inner housing 510 may be attachedor otherwise mechanically coupled to outer housing 502 via divider 504.Inner housing 510 may be disposed in second volume 505 inside outerhousing 502, with a first end coupled to divider 504. In someembodiments, outer housing 502 may be composed of an outer tubing havingan outer diameter of at most ⅜ inches, which may be suitable fordeploying the assembly in coiled tubing.

Fluid entry port 506 may provide a port through outer housing 502 to thefirst volume inside outer housing 502, and compressible element 508 maybe disposed in the first volume. A first end of compressible element 508may be coupled to divider 504, and a second end of compressible element508 may be sealed (e.g., with an end cap).

Large diameter optical waveguide 518 may be at least partially disposedin inner housing 510. In some embodiments, waveguide 518 may bewaveguide 518 a as shown in FIG. 5A. As illustrated, waveguide 518 a maybe composed of a first portion 520, a second portion 524, and a thirdportion 528. A first grating 522 may be disposed in first portion 520 ofwaveguide 518 a, and a second grating 526 may be disposed in secondportion 524 of waveguide 518 a. Second portion 524 may be a singlemember having a diameter larger than that of the first portion 520 andthird portion 528 of waveguide 518 a.

In another embodiment, waveguide 518 may be waveguide 518 b as shown inFIG. 5B. As illustrated, waveguide 518 b may be composed of a firstportion 520, a second portion 530, and a third portion 528. Secondportion 530 may have a “dog-bone” shape, which has two piston portions534 and 536 connected by a piston rod 532 (i.e., a narrow portion) asillustrated in FIG. 5B. A first piston portion 534 may be disposedbetween first portion 520 of waveguide 518 and piston rod 532, and asecond piston portion 536 may be disposed between piston rod 532 andthird portion 528 of waveguide 518. First grating 522 may be disposedwithin first portion 520 of waveguide 518 b, and second grating 526 maybe disposed within piston rod 532 of second portion 530.

The outer diameter of the large diameter optical waveguide may be atleast 300 μm. For some embodiments, large diameter optical waveguide 518may be a monolithic glass assembly.

Large diameter optical waveguide 518 is coupled to a second end of innerhousing 510. In some embodiments, first portion 520 of waveguide 518passes through the second end of inner housing 510.

Pressure imparting member 512 may be composed of a first portion 514 anda second portion 516. First portion 514 of pressure imparting member 512may pass through a bore in divider 504 and may be disposed within aninternal volume of compressible element 508. First portion 514 ofpressure imparting member 512 may be coupled to the second end ofcompressible element 508, and second portion 516 of pressure impartingmember 512 may be coupled to waveguide 518. The second end of pressureimparting member 512 may abut second portion 524 or 530 of waveguide518.

Second portion 516 of pressure imparting member 512 may have one or morefeatures configured to hold large diameter optical waveguide 518. Forexample, second portion 516 may have an internal volume sized to hold,within the internal volume, third portion 528 of waveguide 518. One ormore of the features configured to hold waveguide 518 may furtherprovide an opening for coupling waveguide 518 to an optical fiber thatcan propagate light to interrogate first and second gratings 522, 526 oranother optical sensing assembly.

For some embodiments, one or more flexible members 538 may be disposedbetween and coupled to pressure imparting member 512 and one or moreinner walls of inner housing 510.

In an embodiment, compressible element 508 is a bellows assembly. Thebellows assembly may be, for example, an edge-welded bellows (alsoreferred to as diaphragm bellows), convoluted bellows (also known asformed bellows), or any other type of bellows assembly appropriate foruse in a downhole production environment. The bellows assembly providesfluid isolation and amplification of the pressure imparted fromproduction fluids entering sensing assembly 500 through fluid entry port506. A first end of compressible element 508 may be mounted to divider504 such that compressible element 508 compresses or expands axially inresponse to changes in pressure of a fluid in first volume 503 of outerhousing 502.

For some embodiments, first portion 520 of optical waveguide 518 may becoupled (e.g., via a pigtail) to a first optical fiber 540 thatpropagates light to interrogate the first grating 522 and second grating526. A third portion 528 of optical waveguide 518 may be coupled (e.g.,via a pigtail) to a second optical fiber 542 that propagates light to anoptical device, such as another sensing assembly or a fiber Bragggrating. Sensing assembly 500 may be a single-ended assembly (i.e., anassembly at the end of a fiber optic strand without second optical fiber542) or a pass-through assembly (i.e., an assembly allowing other fiberoptic sensors to be coupled via second optical fiber 542). Thus, secondoptical fiber 542 may be optional. When included, sensing assembly 500(e.g., outer housing 502) may be modified sufficiently to accommodatesecond optical fiber 542.

During operation, sensing assembly 500 may be positioned withinproduction tubing 106 such that fluid entry port 506 is exposed toproduction fluids within the production tubing. Fluid entering outerhousing 502 through fluid entry port 506 may exert axial pressure oncompressible element 508, which may in turn impart an axial loading onwaveguide 518. For example, waveguide 518 may be forced axially againstthe second end of inner housing 510 when compressible element 508 iscompressed axially. Changes in the compression imparted on opticalwaveguide 518 may alter the characteristic wavelengths of gratings 522and 526. Interrogation of gratings 522 and 526 by sensing unit 110 maythus be used to detect changes in pressure and/or temperature at thelocation of sensing assembly 500.

FIG. 6A illustrates an embodiment of a small profile optical sensingassembly 600 suitable for measuring pressure and/or temperature. Sensingassembly 600 is similar to the sensing assembly 500 illustrated in FIG.5A, but with flexible members 538 replaced by a flexible member 632surrounding at least a portion of waveguide 518. One or more retainingmembers 630 may be attached or otherwise mechanically coupled to thefirst end of inner housing 510, and flexible member 632 may be disposedbetween and coupled to second portion 516 of pressure imparting member512 and waveguide 518. For example, flexible member 632 may be a tubularflexure which may encircle large diameter optical waveguide 518. In anembodiment, flexible member 632 may be disposed between retainingmembers 630 and pressure imparting member 512. The length of retainingmembers 630 may be less than the length of second portion 524 ofwaveguide 518, and the length of flexible member 632 may be thedifference between the length of second portion 524 of waveguide 518 andthe length of retaining members 630. Flexible member 632 serves toensure axial alignment and motion of pressure imparting member 512 andwaveguide 518.

A detailed view of an example flexible member 632 is provided in FIG.6B. As illustrated, flexible member 632 may be a monolithic structurehaving a plurality of openings. The plurality of openings may benoncontiguous.

Example Diaphragm Tube Sensing Assembly

FIG. 7 illustrates another embodiment of a small profile pressure andtemperature sensing assembly 700. Sensing assembly 700 may be one of thesensors 112 deployed in the production tubing 106 as described abovewith respect to FIG. 1. As such, sensing assembly 700 may be designed tooperate in environments having an ambient temperature greater than 250°C.

Sensing assembly 700 may include a housing 702, an expandable tube 704,a fluid port 710, and a large diameter optical waveguide 712. In someembodiments, housing 702 may be composed of an outer tubing having anouter diameter of at most ⅜ inches, which may be suitable for deployingthe assembly in coiled tubing. Housing 702 may have fluid port 710positioned through a wall of the housing. Expandable tube 704 may havean internal volume and an inlet 706 coupled to port 710 of housing 702for fluid communication between the internal volume of expandable tube704 and an external volume of housing 702. First and second holdingmembers 708 may be coupled to the expandable tube 704.

Large diameter optical waveguide 712 may be composed of a first portion714 having a first grating 716, a second portion 718 having a secondgrating 720, and a third portion 722. The outer diameter of the largediameter optical waveguide may be at least 300 μm. For some embodiments,large diameter optical waveguide 712 may be a monolithic glass assembly.

First holding member 708 may hold first portion 714 of waveguide 712,and second holding member 708 may hold third portion 722 of waveguide712. In an embodiment, first and second holding members 708 hold largediameter optical waveguide 712 such that pressure increases in a fluidinside the internal volume of expandable tube 704 expands the expandabletube. The expansion of expandable tube 704 thus pulls first and secondholding members 708 closer together, axially compressing waveguide 712.

In an embodiment, first and second holding members 708 may bering-shaped. In this case, first portion 714 of waveguide 712 may passthrough a bore of a first holding member 708, and third portion 722 ofwaveguide 712 may pass through a bore of second holding member 708.Second portion 718 of waveguide 712 may be disposed between the firstand second holding members 708.

In an embodiment, expandable tube 704 may be ring-shaped and encirclewaveguide 712. Inlet 706 may be disposed in an outer sidewall of thering-shaped tube.

In one embodiment, second portion 718 of waveguide 712 may have agreater outer diameter than first portion 714 of waveguide 712. Inanother embodiment, large diameter optical waveguide 712 may have a“dog-bone” shape as illustrated in FIG. 7. For example, second portion718 of waveguide 712 may comprise a rod portion 724 having a first endand a second end. A first piston portion 726 may be disposed at thefirst end of rod portion 724, and a second piston portion 728 may belocated at the second end of rod portion 724.

For some embodiments, first portion 714 of optical waveguide 712 may becoupled (e.g., via a pigtail) to a first optical fiber 730 thatpropagates light to interrogate first grating 716 and second grating720. Third portion 722 of optical waveguide 712 may be coupled to asecond optical fiber 732 that propagates light to an optical device,such as another sensing assembly or a fiber Bragg grating. Sensingassembly 700 may be a single-ended assembly (i.e., an assembly at theend of a fiber optic strand) or a pass-through assembly (i.e., anassembly allowing other fiber optic sensors to be coupled via additionallengths of optical fiber).

In operation, sensing assembly 700 may be positioned in productiontubing 106 such that the wall of housing 702 opposite fluid port 710 isattached, mounted, or otherwise mechanically coupled to the productiontubing and such that fluid port 710 is positioned to allow productionfluids to flow into the space between an inner wall of expandable tube704 coupled to inlet 706 and fluid port 710. As pressure increaseswithin the wellbore, expandable tube 704 is filled and expanded radially(i.e., towards the center of sensing assembly 700), causing first andsecond holding members 708 to compress axially. Likewise, as pressuredecreases within the wellbore, the amount of radial expansion inexpandable tube 704 decreases, allowing holding members 708 to expandaxially. The axial expansion or contraction of holding members 708imparts axial force on optical waveguide 712, causing optical waveguide712 to lengthen or shorten axially, respectively. The expansion orcontraction of optical waveguide 712 causes the characteristicwavelengths of gratings 716 and 720 to change. Sensing unit 110 mayperform an interrogation by transmitting one or more pulses of light togratings 716 and 720. The reflected wavelengths from gratings 716 and720 may be used to determine pressure and/or temperature at the locationof sensing assembly 700.

Example Internally Ported Sensing Assembly

FIG. 8 illustrates another embodiment of a small profile pressure andtemperature sensing assembly 800. Sensing assembly 800 may be one of thesensors 112 deployed in the production tubing 106 as described abovewith respect to FIG. 1. As such, sensing assembly 800 may be designed tooperate in environments having an ambient temperature greater than 250°C.

Sensing assembly 800 may include an outer housing 802, an inner housing804 (e.g., a pressure housing), fluid port 806, and a large diameteroptical waveguide 808. In some embodiments, outer housing 802 may becomposed of an outer tubing having a thickness of at most ¼ inches,which may be suitable for deploying the assembly in coiled tubing. Theouter tubing may be an armored tubing. Inner housing 804 may be at leastpartially disposed within outer housing 802. In some embodiments, innerhousing 804 may comprise a first portion 803 attached to outer housing802 and a second portion 805 that may be narrower in diameter than thefirst portion. Fluid port 806 may be formed from an exterior-facingopening in inner housing 804 and may allow for fluid communicationbetween an internal volume of inner housing 804 and a volume external toouter housing 802. Large diameter optical waveguide 808 may be disposedin the internal volume of inner housing 804. In an embodiment, fluidport 806 is part of the inner housing 804.

Large diameter optical waveguide 808 may have at least a first portion810 with a first grating 812 and a second portion 814 with a secondgrating 816 disposed within a portion of waveguide 808. First portion810 may have a greater outer diameter than second portion 814, which mayhave an outer diameter of at least 300 μm. Waveguide 808 may, in someembodiments, have a substantially “dog-bone” shape, as depicted in FIG.8. For example, first portion 810 of waveguide 808 may be a pistonportion, and second portion 814 of waveguide 808 may be a piston rodportion. The first and third portions of waveguide 808 may have, forexample, a frustoconical shape. The first and third portions ofwaveguide 808 are mated with similarly shaped seats in the first andsecond ends of inner housing 804. A glass-to-metal seal interface 824may provide a seal between a seat of inner housing 804 and waveguide 808(e.g., between the first seat of inner housing 804 and the first portionof waveguide 808, or between the second seat of inner housing 804 andthe third portion of waveguide 808) such that the interior volume ofinner housing 804 is substantially sealed from fluid entry other thanthrough fluid port 806. In some embodiments, one or more V-seals may bedisposed between at least one of the first seat of inner housing 804 andthe first portion 810 of waveguide 808, or the second seat of innerhousing 804 and the third portion of waveguide 808.

In some embodiments, at least a portion of waveguide 808 may be disposedwithin a glass tubing 818. Glass tubing 818 may be, for example,gold-plated to prevent swelling or detrimental effects that may beimparted to waveguide 808 from contact with hydrocarbons. In someembodiments, an enclosed volume between waveguide 808 and glass tubing818 may be filled with air.

The outer diameter of large diameter optical waveguide 808 may be atleast 300 μm. For some embodiments, large diameter optical waveguide 808may be a monolithic glass assembly.

A first end of waveguide 808 may be coupled to an optical fiber 820 thatpropagates light to interrogate gratings 812 and 816. A second end ofwaveguide 808 may be coupled to a second optical fiber 822 thatpropagates light to an optical device, such as another sensing assemblyor a fiber Bragg grating (FBG). Sensing assembly 800 may be asingle-ended assembly (i.e., an assembly at the end of a fiber opticstrand) or a pass-through assembly (i.e., an assembly allowing otherfiber optic sensors to be coupled via additional lengths of opticalfiber). At least one of the optical fibers 820 or 822 or at least oneend of waveguide 808 may pass through a bore in an end of inner housing804.

In operation, sensing assembly 800 may be positioned in productiontubing 106 such that the wall of outer housing 802 opposite fluid port806 is attached, mounted, or otherwise mechanically coupled to theproduction tubing. Production fluids may enter inner housing 804 throughfluid port 806 and impart pressure radially on waveguide 808. Radialpressure imparted on glass tubing 818 may cause waveguide 808 to expandor contract axially, which in turn may cause the characteristicwavelength of gratings 812 and 816 to change. Sensing unit 110 mayperform an interrogation by transmitting one or more pulses of light togratings 812 and 816, and the reflected wavelengths from gratings 812and 816 may be used to determine pressure and/or temperature at thelocation of sensing assembly 800.

CONCLUSION

By using cane-based Bragg gratings in compression in a mechanical framecoupled to a diaphragm or bellows assembly that is exposed to externalpressure, embodiments of the present invention provide stable, accurate,repeatable pressure and temperature sensors with small profiles suitablefor desired applications.

While the foregoing is directed to embodiments of the present invention,other and further embodiments of the invention may be devised withoutdeparting from the basic scope thereof, and the scope thereof isdetermined by the claims that follow.

The invention claimed is:
 1. An optical sensing assembly comprising: anouter housing; an inner housing at least partially disposed in the outerhousing; a port for fluid communication between an internal volume ofthe inner housing and a volume external to the outer housing, whereinthe port is part of the inner housing; and a large diameter opticalwaveguide disposed in the internal volume of the inner housing, whereinthe waveguide comprises: a first portion with a first grating; and asecond portion with a second grating, wherein the outer diameter of thelarge diameter optical waveguide is at least 300 μm.
 2. The assembly ofclaim 1, further comprising a glass tubing, wherein at least a part ofthe large diameter optical waveguide is disposed in the glass tubing. 3.The assembly of claim 2, wherein the glass tubing comprises agold-plated glass.
 4. The assembly of claim 2, wherein an enclosedvolume between the large diameter optical waveguide and the glass tubingis filled with air.
 5. The assembly of claim 1, wherein the firstportion has a greater outer diameter than the second portion and whereinthe outer diameter of the second portion is the at least 300 μm.
 6. Theassembly of claim 5, wherein the large diameter optical waveguide has adog-bone shape, wherein the first portion comprises a piston portion,wherein the second portion comprises a narrow portion, and wherein thelarge diameter optical waveguide comprises a third portion having agreater outer diameter than the second portion.
 7. The assembly of claim6, wherein a first end of the inner housing comprises a first seat formating with the first portion of the large diameter optical waveguideand wherein a second end of the inner housing comprises a second seatfor mating with the third portion of the large diameter opticalwaveguide.
 8. The assembly of claim 7, further comprising one or moreV-seals between at least one of: the first seat of the inner housing andthe first portion of the large diameter optical waveguide; or the secondseat of the inner housing and the third portion of the large diameteroptical waveguide.
 9. The assembly of claim 6, wherein at least one ofthe first portion or the third portion of the large diameter opticalwaveguide has a frustoconical shape.
 10. The assembly of claim 1,wherein at least one end of the large diameter optical waveguide iscoupled to an optical fiber that propagates light to interrogate thefirst and second gratings.
 11. The assembly of claim 10, wherein atleast one of the optical fiber or the at least one end of the largediameter optical waveguide passes through a bore in an end of the innerhousing.
 12. The assembly of claim 1, wherein the outer housing has anouter diameter of at most ¼ inches.
 13. The assembly of claim 1, whereinthe large diameter optical waveguide is a monolithic glass assembly. 14.The assembly of claim 1, wherein the outer housing comprises armoredtubing.
 15. The assembly of claim 1, wherein the port passes radiallythrough the outer housing with respect to an axis of the waveguide. 16.An optical sensing assembly comprising: an outer housing; an innerhousing at least partially disposed in the outer housing; a port forfluid communication between an internal volume of the inner housing anda volume external to the outer housing; and a large diameter opticalwaveguide disposed in the internal volume of the inner housing, whereinthe waveguide comprises: a first portion with a first grating; a secondportion with a second grating, wherein the outer diameter of the largediameter optical waveguide is at least 300 μm; and a third portionhaving a greater outer diameter than the second portion, wherein a firstend of the inner housing comprises a first seat for mating with thefirst portion of the large diameter optical waveguide and wherein asecond end of the inner housing comprises a second seat for mating withthe third portion of the large diameter optical waveguide.
 17. Theassembly of claim 16, wherein the first portion has a greater outerdiameter than the second portion and wherein the outer diameter of thesecond portion is the at least 300 μm.
 18. The assembly of claim 17,wherein the large diameter optical waveguide has a dog-bone shape,wherein the first portion comprises a piston portion, and wherein thesecond portion comprises a narrow portion.
 19. The assembly of claim 16,further comprising one or more V-seals between at least one of: thefirst seat of the inner housing and the first portion of the largediameter optical waveguide; or the second seat of the inner housing andthe third portion of the large diameter optical waveguide.
 20. Theassembly of claim 16, wherein: at least one end of the large diameteroptical waveguide is coupled to an optical fiber that propagates lightto interrogate the first and second gratings; and at least one of theoptical fiber or the at least one end of the large diameter opticalwaveguide passes through a bore in the first end or the second end ofthe inner housing.
 21. The assembly of claim 16, wherein at least one ofthe first portion or the third portion of the large diameter opticalwaveguide has a frustoconical shape.